Design, engineering, and manufacturing are undergoing a digital transformation, and the need for a collaborative product development environment is becoming an ever-growing requirement. Autodesk® Fusion 360™ meets this need by connecting CAD, CAM, and CAE in a single cloud-based platform unlike any other tool of its kind. This course builds upon digital manufacturing trends and foundational CAD concepts discussed in Course 1 of this series by introducing Fusion 360 as a problem-solving tool. In this course, we take the next step in connecting CAD, CAM, and CAE through a series of short exercises on 3D modeling, rendering, simulation, and computer aided manufacturing.
After completing this course series, you will be able to:
• Demonstrate knowledge of and apply job entry level skills in computer aided design, computer aided engineering (CAE) and computer aided manufacturing (CAM) using Fusion 360 software.
• Describe and apply design based workflows for design, engineering and manufacturing using Fusion 360 software.
• Utilize Fusion 360 cloud based collaboration features for project sharing and design review.

AW

This course has given me what I wanted...….. to explore the best CAD, CAM software in the world. In the end I would like to say ' Thank you' Autodesk and Coursera

SS

Jul 29, 2018

Filled StarFilled StarFilled StarFilled StarFilled Star

Best Course i completed Autodesk fusion 360. It gives you single detail how to work on AUTODESK FUSION 360. Finally It is very helpful to me.

从本节课中

CAM and 3D printing resources

Fusion 360 is the first 3D CAD, CAM, and CAE tool of its kind. It connects your entire product development process in a single cloud-based solution supporting the digital manufacturing process. With Fusion 360, you can create toolpaths to machine your components or use the 3D printing workflow to create a design prototype. This week covers the basics of CAM and 3D printing using Fusion 360.

教学方

Autodesk Education

脚本

Working in the FSAE steering wheel cam file, let's begin to cut the shape of the part. We'll start by going to the 2D drop down and selecting 2D Contour tool path. In the tool tab of the 2D CONTOUR dialog, it is carried over the spot drill from the previous operations. We'll select the different tool from the library. Going to the filters, I'll remove all the options except for the flat and mil. You can use the Clear option in the lower left to speed up this process if you like. We'll also sort by dimensions. Setting a range from 0.25 to 1 inch, and select the diameter checkbox and pick OK to update the list. In the list of tools set up for aluminum, select the 1/2 inch Endmill and click OK. Moving to the Geometry tab, we need to select the geometry that will make up the exterior profile of the part. It's important to note that the edge that is selected will act as a guide for the cutting depth. So we'll select the bottom exterior edge of the part. On the Heights tab, we can see the clearance height is set to 0.4 inches above the retract height, which is 0.2 inches above the stock top, which also has the feed height and top height based on it. These relationships can be changed if needed and are very important to get the proper cut without damaging the part or tooling. On the Passes tab, we can set Climb or Conventional milling. We can set the compensation type. This, I'll set it to Wear, so that if the part ends up oversized due to tool wear, we can update the path on the machine. I'll select multiple finishing passes and set the value to 2. I'll also set the roughing passes to a maximum step over of 0.475 inches. On the Linking tab we'll leave everything as default, including the lead in which will help keep the tooling load consistent. We will turn on the Ramp option because we aren't setting up a multiple depth cut. Again, this will help with tool loading. Let' click OK to generate the tool path and look at the results. I can see the bottom cutting pass in blue are all the way down the part. Now let's save the file.